KR200301522Y1 - Power supply cutoff in electric structure on the road - Google Patents

Abstract

The present invention is a conventional roadside electrical facility power cut-off device, the sensor unit including a sensor for detecting the water level of the roadbed electrical facility, and installed in the KEPCO, the primary side of the KEPCO receives the signal generated from the sensor An on-board electrical facility power cut-off device, comprising: a primary power cut-off unit for opening and closing a connection between a power line and a secondary-side power line; and a signal transmission device for transmitting a signal between the sensor unit and the primary power cut-off unit. By providing a, it is possible to prevent the electrocution caused by the submersion of the underground line by making the underground line inactive by disconnecting the primary and secondary power lines if there is a risk of flooding. It can prevent the failure of electric facilities which may be caused by short circuit.

Description

POWER SUPPLY CUTOFF IN ELECTRIC STRUCTURE ON THE ROAD}

The present invention relates to a power cut-off device for a roadbed electrical facility, and more particularly, to a power cut-off device for a roadbed electrical facility for preventing an electric shock caused by a short circuit during flooding of the roadbed electrical facility.

The roadside electrical facilities refer to electrical facilities such as street lamps and traffic lights installed on the streets, and recent occurrences of such electrical facilities are frequently flooded due to heavy rains. Also, when the electrical facilities are flooded, the surroundings of the electrical facilities are Many people who passed by were electrocuted.

1 is a conceptual diagram showing the configuration of a conventional electric facility.

As shown, a roadside electrical facility 10 such as a street lamp or a traffic light is installed, and the enclosure 30 for power distribution and control of the roadside electrical facility 10 includes the roadside electrical facility 10 and a tertiary side power line. Connected by 23, the columnar transformer 41 and the housing 30 of the KEPCO 40 to supply power to the housing 30 and the roadbed electrical facility 10, the secondary power line ( 22).

In addition, a ground fault breaker (not shown) is installed in the lower ground section of the roadside electrical facility 10 to operate when a short circuit occurs in the roadside electrical facility 10.

Hereinafter, the operation of a conventional electric facility will be described.

In a typical case, power is supplied to the enclosure 30 through the secondary power line 22 in the columnar transformer 41, and the enclosure 30 is connected to the roadbed electrical facility 10 according to a predetermined control signal. ) To supply power through the tertiary side power supply line 23.

In addition, when a heavy rain or the like occurs and the roadbed electrical facility 10 is submerged in water, an earth leakage breaker (not shown) installed in the roadbed electrical facility 10 operates to cut off the power.

However, even when the ground fault breaker (green) is operated, the secondary power line 22 is still active, and the housing 30 is also in a state where current flows. Therefore, a short circuit may occur in the secondary power line 22 and the housing 30 due to the flooding, which causes a problem of human injury and damage to the facility.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a power cut-off device for roadbed electrical facilities that prevent the leakage of power from the secondary power line and the enclosure during flooding.

1 is a conceptual diagram showing the configuration of a conventional electric facility

2 to 4 show the structure of the first embodiment of the present invention,

2 is a conceptual diagram of a power cut-off device for roadbed electric facilities

3 is a conceptual diagram of a sensor unit of FIG.

4 is a conceptual diagram of a primary power interrupter of FIG.

5 and 6 illustrate the configuration of a second embodiment of the present invention.

5 is a conceptual diagram of the sensor unit

6 is a conceptual diagram of a power interruption device;

** Description of the symbols for the main parts of the drawings **

10: roadside electrical facility 21: primary power line

22: secondary power line 30: sensor

40: KEPCO 151: Sensor

156: manual switch 157: sensor module

158: sensor communication module 170: primary power cut-off unit

171: actuator module 172: input relay

173: disconnect relay 174: magnetic switch

175: power communication module breaker

The present invention is a sensor unit including a sensor for detecting the water level of the roadbed electrical facilities, and in order to achieve the object described above, is installed on the KEPCO, receiving the signal generated from the sensor unit power supply to the primary side of the KEPCO Provides a roadside electrical facility power cut-off device comprising a primary power cut-off unit for opening and closing the connection of the line and the secondary power line, and a signal transmission device for transmitting a signal between the sensor unit and the primary power cut-off unit.

Therefore, if there is a risk of flooding, by disconnecting the primary power supply line and the secondary power supply line, the underground line becomes inactive and prevents electrocution that may occur due to flooding of the underground line. It can prevent the failure of electrical facilities.

In addition, the primary power cut-off unit is connected to the primary power line and the secondary power line, a magnetic switch that can open and close the connection of the primary power line and the secondary power line, and is connected to the magnetic switch, to operate the magnetic switch And a shutoff relay for cutting off the connection between the primary power line and the secondary power line, and an actuator module connected to the signal transmission device and operating the cutoff relay according to the cutoff signal received from the signal transmission device. desirable.

The sensor unit is connected to the sensor, the signal transmission device is connected, and the manual open / close switch is connected to the user to open and close the magnetic switch, and opens and closes according to the signal of the sensor and the signal of the manual open / close switch. It further comprises a sensor module for transmitting a signal to the signal transmission device, wherein the primary power cut-off unit is connected to the magnetic switch and the actuator module, by operating the magnetic switch in accordance with the signal of the actuator module and the primary power line 2 It further comprises an input relay for connecting the vehicle side power line, wherein the actuator module is preferably configured to operate the input relay in accordance with the input signal received from the signal transmission device.

Therefore, the user can easily restart the electrical installation and can be easily tested to increase the reliability of the circuit breaker.

The signal transmission device may include a sensor power communication module installed at the secondary power line coupling unit of the sensor unit and configured to perform power line communication, and a power line communication unit installed at the secondary power line coupling unit of the primary power cutoff unit. Preferably, it is configured to include a breaker power communication module configured to.

Therefore, operation is possible without the need for a separate communication line.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

However, in describing the present invention, a detailed description of known functions or configurations will be omitted in order not to disturb the gist of the present invention.

In addition, the same reference numerals are given to the same and the same components as those described above, and detailed description thereof will be omitted.

2 to 4 show the structure of the first embodiment of the present invention, FIG. 2 is a conceptual view of a power cut-off device for a roadbed electrical facility, FIG. 3 is a conceptual view of the sensor unit of FIG. 2, and FIG. 4 is a primary power supply of FIG. It is a conceptual diagram of the blocking part.

As shown in FIG. 2, the power cut-off device for the roadbed of the first embodiment of the present invention is installed in the enclosure 30, and includes a sensor unit 150 for detecting the water level of the roadbed 10. Is installed in the 40, and connected by the columnar transformer 41 and the primary power line, and connected by the enclosure 30 and the secondary side power line 22 in accordance with the signal of the sensor unit 150 A signal between the primary power cutoff unit 170 that opens and closes the connection between the primary power line 21 and the secondary power line 22, and a signal between the sensor unit 150 and the primary power cutoff unit 170. It is configured to include a signal transmission device (not shown) for transmitting.

The enclosure 30 and the roadbed electrical facility 10 are connected by a tertiary side power line 23.

The signal transmission device (not shown) is configured to perform power line communication using the secondary power line 22 between the sensor unit 150 and the primary power cut-off unit 170. Power line communication is a communication through a power line that transmits and receives power. High speed power line communication used for the Internet or data network with a transmission speed of 1 Mbps to 10 Mbps, and 60 bps-1 Mbps for control and measurement. There is become low speed power line communication. High speed power line communication has been developed by many companies such as Nortel and Simens, and low speed power line communication has been developed by Achelon. The present invention controls the primary power cutoff unit 170 using low speed power line communication.

The signal transmission device (not shown) may be installed at the secondary power line coupling part of the sensor unit 150 to provide power line communication with the sensor unit power communication module 158 and the primary power cutoff unit 170. The secondary power supply line 22 is configured to include a blocker power communication module 175 installed in the coupling portion and configured to perform power line communication.

The sensor unit 150 is installed between a plurality of input contacts 152-154, a sensor unit contact 159 for outputting an output signal, and the input contact 152-154 and the sensor unit contact 159. A sensor for sensing a level of the sensor module 157 and the roadbed electrical facility 10 through which the signal of the input contact 152-154 is transmitted to the sensor contact 159 through the sensor power communication module 158. And 151.

The input contact point 152-154 may include a sensor input contact point 152 connected to the sensor 151, a parking short circuit input contact point 153 connected to an earth leakage breaker (not shown) of the electrical facility 10, and It consists of an extra input contact 154.

The sensor 151 is preferably a fruit switch. However, the sensor 151 may also be configured as an electrode sensor or an ultrasonic switch. In addition, if the water level can be detected, other sensors can be used, and two or more sensors can be configured for reliability.

The manual open / close switch 156 is connected to the sensor module 157.

The sensor module 157 transmits an open / close signal to the sensor unit contact 159 according to the signals of the input contacts 152-154 and the manual open / close switch 156.

In addition, the sensor unit power communication module 158 and the sensor module 157 may be implemented as one microprocessor.

FIG. 4 is a conceptual diagram of the primary power interrupter of FIG. 2.

The primary power cutoff unit 170 may be connected to the primary power line 21 and the secondary power line 22 to open or close a connection between the primary power line 21 and the secondary power line 22. A magnetic switch 174, a blocking relay 173 for blocking the magnetic switch 174, an input relay 172 for turning on the magnetic switch 174, the blocking relay 173 and the input relay It comprises a actuator module 171 for controlling the (172).

The actuator module 171 is connected by the input relay 172 and the input relay signal lines D0 and D1, and are connected by the blocking relay 173 and the blocking relay signal lines S0 and S1. The power communication module 175 is connected to the communication module signal lines C1 and C2, and is connected to the primary power line 21.

The input relay 172 is connected to the input relay terminals M1 and M6 of the magnetic switch 174, and the power is connected to the secondary power supply line 22 by the input relay power supply lines P4 and P3. Becomes

The cutoff relay 173 is connected to the cutoff relay terminal M4 of the magnetic switch 174 and is connected to the primary power line by the cutoff relay power lines P2 and P3.

The power communication module 175 is directly connected to the secondary power line 22. The power communication module 175 may be integrally formed with the actuator module 171.

The magnetic switch is connected to the secondary power line 22 and the secondary power line terminals M7-M10, and the primary power line 22 to connect the secondary power line 22 to the primary power line 21. It is connected to the primary power line 21 by the power line terminals M2 and M5, and the primary power line 21 and the magnetic switch terminals M3 and M4 for supplying power to the magnetic switch 174 itself. ) Is connected. However, the magnetic switch terminal M4 is connected to the blocking relay to receive power.

Hereinafter, the operation of the first embodiment of the present invention will be described.

In general, electricity flows from the columnar transformer 41 to the secondary power line 22 through the primary power cutoff unit 170 through the primary power line 21. In addition, the power introduced through the secondary side power line 22 is supplied to the enclosure 30, the enclosure 30 is connected to the roadside electrical facility 10 in accordance with a predetermined control signal to the tertiary side power line ( Supply power through 23).

In the primary power cutoff unit 170, the primary side power line 21 and the secondary side power line 22 are connected through the M2, M5, M8, and M9 terminals of the magnetic switch 174.

When a heavy rain occurs and the water level rises, the sensor 151 detects the water level and sends a signal to the sensor module 157 when the water level becomes higher than the dangerous water level. The sensor module 157 sends a signal to the sensor unit power communication module 158, and the sensor unit power communication module 158 transmits the breaker unit power communication module 158 through the secondary power line 22. Will be signaled to The cut-off power communication module 175 transmits the signal to the actuator module 171 through communication module signal lines C1 and C2. The actuator module 171 operates the blocking relay 173 through the blocking relay signal lines S0 and S1, and the blocking relay 173 operates the magnetic switch 174 to operate with the primary power line 21. The secondary power line 22 is disconnected. In addition, even before the dangerous water level is reached, when an earth leakage breaker (not shown) installed in the roadbed electrical facility 10 is operated, a signal is input through the parking short circuit input contact point 153, and the same process is performed. The secondary power line 21 and the secondary power line 22 are disconnected.

As described above, the present invention cuts the connection between the primary power line 21 and the secondary power line 22 when there is a risk of flooding, and the ground wire becomes inactive, thereby preventing electrocution that may occur due to flooding of the ground wire. It can also prevent, and can also prevent the failure of the electrical facilities that may be caused by a short circuit during the flooding of the enclosure (30).

In addition, by using power line communication as a communication method, it is possible to operate without the need for a separate communication line.

In addition, even if the sensor does not operate, it is configured to disconnect the primary power supply line and the secondary power supply line when the ground fault breaker is operated, thereby improving the reliability of the breaker.

When the water level is reduced and the safety inspection is finished, and the user operates the roadbed electrical facility using the manual open / close switch 156 of the sensor unit 150, the sensor module 157 generates a signal. And, it is transmitted to the actuator module 171 through the secondary power line 22, the actuator module 271 operates the closing relay 172 to operate the magnetic switch 174 to the The primary power supply line 21 and the secondary power supply line are connected.

In order to test the power cut-off device of the roadbed electrical facility, when the user operates the manual opening / closing switch 156 of the sensor unit 150 to cut off the power, the sensor module 157 generates a signal, and the secondary power source. The actuator module 171 is transmitted to the actuator module 171 through a line 22, and the actuator module 271 operates the blocking relay 173 to operate the magnetic switch 174 to operate the primary power line ( 21) and disconnect the secondary power line.

As described above, the present invention can be restarted the electrical installation in the housing 30 is easy to manage.

In addition, since the performance of the electrical facility breaker can be tested in the enclosure 30, the breaker can be known in advance, thereby increasing the reliability of the breaker.

5 and 6 show the configuration of the second embodiment of the present invention, FIG. 5 is a conceptual diagram of a sensor unit, and FIG. 6 is a conceptual diagram of a power cutoff device.

The second embodiment differs only in the configuration of the signal transmission device from the first embodiment, and the other configurations are the same.

The signal transmission device (not shown) is configured to perform wireless communication between the sensor unit 150 and the primary power cutoff unit 170.

The signal transmission device (not shown) includes a sensor unit wireless communication module 258 connected to the sensor module 157 of the sensor unit 150, and a sensor unit antenna 259 connected to the sensor unit wireless communication module 258. And a blocking unit wireless communication module 275 connected to the actuator module 171 of the primary power blocking unit 170, and a blocking unit antenna 276 connected to the blocking unit wireless communication module 275. Is configured to enable wireless communication between the sensor unit 150 and the primary power cut-off unit 170.

In the above described a preferred embodiment of the present invention by way of example, the scope of the present invention is not limited only to this specific embodiment, it can be appropriately changed within the scope described in the utility model registration claims.

For example, the present invention proposes a power line communication or a wireless communication method for the configuration of the signal transmission device in an advanced form. In addition, the signal transmission device is a general wire that connects the sensor module 157 and the actuator module 157. It is possible to configure using a communication line (not shown), and it is also possible to configure using two or more communication methods at the same time to ensure reliability.

In addition, the present invention uses a magnetic switch and a relay as a power cut-off device of the primary power cut-off unit, but can also be implemented by other electric circuit methods, which also belongs to the claims of the present invention.

According to the embodiment of the present invention as described above it can be expected a variety of effects, including the following. However, the present invention is not achieved only if all of the following effects.

First, if there is a risk of flooding, by disconnecting the primary and secondary power lines, the underground line becomes inactive, which prevents electrocution that may occur due to flooding of the underground line. This can prevent the failure of electrical facilities that can occur.

In addition, by using power line communication as a communication method, it is possible to operate without the need for a separate communication line.

In addition, even if the sensor does not operate, it is configured to disconnect the primary power supply line and the secondary power supply line when the ground fault breaker is operated, thereby improving the reliability of the breaker.

In addition, the present invention can be restarted the electrical installation in the housing and easy to manage.

In addition, since the performance of the electrical facility breaker can be tested in the enclosure, it is possible to know the failure of the breaker in advance, thereby increasing the reliability of the breaker.

Claims (9)

A sensor unit including a sensor for detecting a water level of the roadbed electrical facility; A primary power cut-off unit installed in the KEPCO pole and receiving the signal generated by the sensor unit to open and close the connection between the primary power line and the secondary power line of the KEPCO pole; A signal transmission device for transmitting a signal between the sensor unit and the primary power cutoff unit; Power cut-off device for roadbed electrical facility comprising a. The method of claim 1, wherein the primary power interrupting unit A magnetic switch connected to the primary power supply line and the secondary power supply line and capable of opening and closing a connection between the primary power supply line and the secondary power supply line; A disconnect relay connected to the magnetic switch to operate the magnetic switch to cut off the connection between the primary power line and the secondary power line; An actuator module connected to the signal transmission device and configured to operate the cutoff relay according to a cutoff signal received from the signal transfer device; Power cut-off device for roadbed electrical facility comprising a. The method of claim 2, The sensor unit is connected to the sensor, the signal transmission device is connected, the manual open and close switch is connected to the user to open and close the magnetic switch, according to the signal of the sensor and the signal of the manual open and close switch to open and close the signal It further comprises a sensor module for transmitting to the signal transmission device; The primary power cut-off unit further includes an input relay connected to the magnetic switch and the actuator module, and operating a magnetic switch according to a signal of the actuator module to connect the primary power line and the secondary power line; And said actuator module is configured to operate an input relay according to an input signal received from said signal transmission device. The sensor according to any one of claims 1 to 3, wherein the sensor is Power cut-off device for roadbed electrical facility, characterized in that the fruit switch. The sensor according to any one of claims 1 to 3, wherein the sensor is The power cut-off device of the roadbed electrical facility, characterized in that the electrode switch. The sensor according to any one of claims 1 to 3, wherein the sensor is Power cut-off device for roadbed electrical facility, characterized in that the ultrasonic switch. The apparatus of any one of claims 1 to 3, wherein the signaling device A sensor unit power communication module installed at the secondary power line coupling unit of the sensor unit and configured to perform power line communication; A cutoff unit power communication module installed at the secondary power line coupling unit of the primary power cutoff unit and configured to perform power line communication with the sensor unit power communication module; Power cut-off device for roadbed electrical facility comprising a. The apparatus of any one of claims 1 to 3, wherein the signaling device A sensor unit wireless communication module connected to the sensor unit and configured to perform wireless communication; A cutoff unit wireless communication module connected to the primary power cutoff unit and configured to perform wireless communication with the sensor unit wireless communication module; Power cut-off device for roadbed electrical facility comprising a. The method of claim 3, wherein the signal transmission device A power cut-off device for a roadside electrical facility comprising a wired communication line connecting the sensor module and the actuator module and transmitting a signal between the sensor module and the actuator module.